Formation of a simple cubic antiferromagnet through charge ordering in a double Dirac material

The appearance of spontaneous charge order in chemical systems is often associated with the emergence of novel, and useful, properties. Here we show through single crystal diffraction that the Eu ions in the mixed valent metal EuPd$_3$S$_4$ undergo long-range charge ordering at $T_{\mathrm{CO}} = 340 \mathrm{~K}$ resulting in simple cubic lattices of Eu$^{2+}$ ($J = 7/2$) and Eu$^{3+}$ ($J = 0$) ions. As only one of the two sublattices has a non-magnetic ground state, the charge order results in the emergence of remarkably simple G-type antiferromagnetic order at $T_{\mathrm{N}} = 2.85(6) \mathrm{~K}$, observed in magnetization, specific heat, and neutron diffraction. Application of a $0.3 \mathrm{~T}$ field is sufficient to induce a spin flop transition to a magnetically polarized, but still charge ordered, state. Density functional theory calculations show that this charge order also modifies the electronic degeneracies present in the material: without charge order, EuPd$_3$S$_4$ is an example of a double Dirac material containing 8-fold degenerate electronic states, greater than the maximum degeneracy of six possible in molecular systems. The symmetry reduction from charge order transmutes 8-fold double Dirac states into 4-fold Dirac states, a degeneracy that can be preserved even in the presence of the magnetic order. Our results show not only how charge order can be used to produce interesting magnetic lattices, but also how it can be used to engineer controlled degeneracies in electronic states.

[1]  C. Felser,et al.  Bonding and Electronic Nature of the Anionic Framework in LaPd3S4 , 2022, Chemistry of Materials.

[2]  Tyler J. Slade,et al.  Use of Refractory‐Volatile Element Deep Eutectic Regions to Grow Single Crystalline Intermetallic Compounds , 2022, Zeitschrift für anorganische und allgemeine Chemie.

[3]  T. McQueen,et al.  Antiferro- and metamagnetism in the S=7/2 hollandite analog EuGa2Sb2 , 2021, Physical Review Materials.

[4]  Stephen D. Wilson,et al.  CsV_{3}Sb_{5}: A Z_{2} Topological Kagome Metal with a Superconducting Ground State. , 2020, Physical review letters.

[5]  A. Zunger,et al.  False metals, real insulators, and degenerate gapped metals , 2020, 2008.07694.

[6]  T. McQueen,et al.  Laser-Enhanced Single Crystal Growth of Non-Symmorphic Materials: Applications to an Eight-Fold Fermion Candidate , 2020 .

[7]  R. Cava,et al.  Homogeneous reduced moment in a gapful scalar chiral kagome antiferromagnet. , 2019, Physical review. B.

[8]  A. Scheie LongHCPulse: Long-Pulse Heat Capacity on a Quantum Design PPMS , 2017, Journal of Low Temperature Physics.

[9]  E. J. Mele,et al.  Weyl and Dirac semimetals in three-dimensional solids , 2017, 1705.01111.

[10]  C. Felser,et al.  Beyond Dirac and Weyl fermions: Unconventional quasiparticles in conventional crystals , 2016, Science.

[11]  C. Kane,et al.  Double Dirac Semimetals in Three Dimensions. , 2015, Physical review letters.

[12]  P. Canfield,et al.  Use of frit-disc crucibles for routine and exploratory solution growth of single crystalline samples , 2015, 1509.08131.

[13]  G. Sheldrick SHELXT – Integrated space-group and crystal-structure determination , 2015, Acta crystallographica. Section A, Foundations and advances.

[14]  Y. Zhao,et al.  Double-Focusing Thermal Triple-Axis Spectrometer at the NCNR , 2012, Journal of research of the National Institute of Standards and Technology.

[15]  M Zahid Hasan,et al.  Three-Dimensional Topological Insulators , 2010, Annual Review of Condensed Matter Physics.

[16]  John R. D. Copley,et al.  DAVE: A Comprehensive Software Suite for the Reduction, Visualization, and Analysis of Low Energy Neutron Spectroscopic Data , 2009, Journal of research of the National Institute of Standards and Technology.

[17]  T. Takabatake,et al.  Heterogeneous Mixed-Valence States in RPd3S4 (R=Eu and Yb) Viewed from Thermopower, Electrical Resistivity and Specific Heat , 2002 .

[18]  G. Ódor Universality classes in nonequilibrium lattice systems , 2002, cond-mat/0205644.

[19]  K. Ohoyama,et al.  Powder neutron diffraction study on TbPd3S4 and YbPd3S4 , 2001 .

[20]  Y. Hinatsu,et al.  Mössbauer Effects and Magnetic Properties of Mixed Valent Europium Sulfide, EuPd3S4 , 2001 .

[21]  A. S Wills,et al.  A new protocol for the determination of magnetic structures using simulated annealing and representational analysis (SARAh) , 2000 .

[22]  Schmitt,et al.  Specific heat in some gadolinium compounds. I. Experimental. , 1991, Physical review. B, Condensed matter.

[23]  G. Squires,et al.  Introduction to the Theory of Thermal Neutron Scattering , 1978 .

[24]  G. Ahlers,et al.  Universality of the specific heat of Heisenberg magnets near the critical temperature , 1975 .

[25]  G. Ahlers,et al.  Heat capacity of EuO near the Curie temperature , 1975 .

[26]  J. R. Granada,et al.  Neutron Scattering Lengths and Cross Sections , 2013 .

[27]  G. Sheldrick A short history of SHELX. , 2008, Acta crystallographica. Section A, Foundations of crystallography.

[28]  Hans Wondratschek,et al.  Bilbao Crystallographic Server: I. Databases and crystallographic computing programs , 2006 .

[29]  Sydney Hall,et al.  International Tables for Crystallography , 2005 .

[30]  Juan Rodriguez-Carvaj,et al.  Recent advances in magnetic structure determination neutron powder diffraction , 1993 .

[31]  J. Ibers,et al.  Preparation, characterization, and physical properties of the series MPd3S4(M = rare earth) , 1985 .

[32]  S. W. Lovesey,et al.  Theory of neutron scattering from condensed matter , 1984 .